Burner for a heater device with improved fuel supply

ABSTRACT

A burner for a heater, especially for use in motor vehicles, with a burner nozzle ( 12 ) for supplying and atomizing of fuel, which has a fuel needle ( 14 ) for supplying fuel to the burner ( 10 ) and a combustion air supply ( 16 ) for supplying combustion air to the burner, and a starting zone ( 18 ) in which ignition of the fuel to start the burner takes place. It is provided that, by choosing the inside diameter of the fuel needle ( 14 ) the exit speed of the fuel is predetermined such that, during the starting phase of the burner ( 10 ), fuel in essentially unatomized form reaches the starting zone ( 18 ).

BACKGROUND OF THE INVENTION

1. Field of Invention

The invention relates to a burner for a heater, especially for use in motor vehicles, with a burner nozzle for supply and atomization of fuel, which has a fuel needle for supplying fuel to the burner and a combustion air supply for supplying combustion air to the burner, and a starting zone in which ignition of the fuel to start the burner takes place.

2. Description of Related Art

Burners of the initially mentioned type, which are also called atomization burners or spray burners, are used especially in auxiliary heaters and engine independent heaters for motor vehicles.

There are numerous requirements for these burners, especially with respect to reliable and largely emission-free starting behavior and stable combustion operation. Furthermore, an effort is made to build heaters which can be used in different installation positions.

With respect to starting behavior, various operating parameters must be matched to one another. On the one hand, it is necessary during burner starting to make available a relatively rich fuel-air mixture in the starting zone, and on the other hand, however, providing a sufficient amount of primary combustion air is necessary to ensure transport of fuel from the fuel needle to the starting zone.

The requirement of allowing different installation positions of the heater is associated with problems relating to starting behavior. In order to be specifically able to transport fuel into the starting zone with little primary air supply, in the past, orienting the fuel needle with the outlet opening pointed down had to be tolerated; this resulted in the entire burner having to be mounted in the vertical installation position.

To ensure stable combustion operation of the burner, likewise, mutually contradictory requirements must be satisfied. On the one hand, good intermixing of the fuel and air is always required, and on the other hand, in the core region of the flame, especially during the starting phase, it is undesirable to cause overly high air proportions and overly high swirling.

SUMMARY OF THE INVENTION

The object of the invention is to overcome the described problems of the prior art at least in part and especially to enable reliable and low-emission starting behavior with little dense smoke in different installation positions.

This object is achieved by the exit speed of the fuel being predetermined by choosing the inside diameter of the fuel needle such that, during the starting phase of the burner, fuel in essentially unatomized form reaches the starting zone.

The invention is based on a generic burner in that, by choosing the inside diameter of the fuel needle, the exit speed of the fuel is predetermined such that, during the starting phase of the burner, fuel in essentially unatomized form reaches the starting zone. By reducing the inside diameter of the fuel needle as compared to fuel needles in the heaters of the prior art, at the same fuel delivery volume, the exit speed of the fuel is increased. In this way, for any installation position, it is possible for the fuel jet to reach the starting zone from the exit opening of the fuel needle. In particular, for a small primary air amount, for which the supplied primary air should have only little angular momentum, an essentially unatomized fuel jet can reach the starting zone. Consequently, the burner starts reliably and formation of dense smoke during starting is distinctly reduced.

It is preferred that the inside diameter of the fuel needle be between 0.5 mm and 0.7 mm. Compared to exit speeds for fuel needles of the prior art in which the inside diameter is in the region of 0.8 mm, the exit speed for inside diameters between 0.5 mm and 0.7 mm can be almost doubled or even more than doubled.

It is especially preferred that the inside diameter of the fuel needle is roughly 0.6 mm. At this inside diameter, in full load operation, i.e., at a fuel mass flow of 0.5 kg/h, exit speeds of more than 0.6 m/s are possible, while for an inside diameter of 0.8 mm, the exit speed is in the region of 0.35 m/s. The exit speed in partial load operation rises accordingly, i.e., for a fuel mass flow of 0.2 kg/h, from roughly 0.14 m/s to roughly 0.25 nm/s. For a corresponding choice of construction properties or of operating parameters, the goal of an essentially unatomized jet which reaches the starting zone when the heater is being started can be achieved even with an otherwise conventional fuel needle with an inside diameter of roughly 0.8 mm.

It is useful for the starting zone to be made as a starting chamber into which an ignition element projects. The wall of the combustion chamber can surround the ignition element in this way. During starting operation, the “ballistic” fuel jet can then wet the ignition element and the combustion chamber wall with fuel so that the combustion chamber wall and adjacent components, after being heated, are used as wall vaporizers.

According to one especially preferred embodiment of this invention, it is provided that, in addition to the primary air which is supplied from the burner nozzle through a heat shield located between the burner nozzle and the combustion chamber, secondary air can be supplied to the combustion chamber through openings provided in the heat shield, and that the openings are provided with air guide elements. A heat shield is fundamentally useful to shield the nozzle and the fuel supply against the heat energy present in the combustion chamber. Furthermore, secondary air is supplied to the combustion space via the heat shield. By the openings for secondary air supply being provided with air guide elements, this secondary air can be supplied in a controlled manner so that combustion operation, both with respect to starting operation and also for continuous operation, can be influenced in a specific manner.

It is useful for the air guide elements to be formed by tabs which are made integrally with the heat shield and which project in the direction of the combustion chamber. This heat shield can be easily produced, for example, by the tabs being formed with a v-shaped punching tool and being bent out of the plane of the heat shield after or with the punching process.

The invention is also usefully developed in that the tabs are made at different angles to the surface of the heat shield and/or to the radius of the heat shield. If the tabs extend almost perpendicularly to the radius of the heat shield, this delivers strong angular momentum, while tabs with a smaller angle relative to the radius deliver smaller angular momentum. Tabs which assume a small angle to the surface of the heat shield produce air flows which have a large radial component and a small axial component, while for tabs with large angles relative to the surface of the heat shield, the axial component dominates. In this way, it is possible to route secondary air with low angular momentum into the core region of flame formation. Thus, on the one hand, the air required for combustion is supplied; but there is no excess angular momentum which would adversely affect stabilization of the flame. In particular, the secondary air can be divided depending on the alignment of the individual air guide elements.

According to another embodiment, it is provided that the tabs are grouped at essentially identical angles relative to the surface of the heat shield and/or to the radius of the heat shield. Defined flow states in the combustion chamber are formed by the collective alignment of the tabs.

The invention is also usefully executed such that the burner has a burnout zone and that the secondary air which is supplied to the burnout zone has higher angular momentum than the secondary air which is supplied to the starting zone. High angular momentum is desired in the burnout zone. In particular, a radially inside swirled backflow region improves the burnout and provides for the combustion chamber volume being effectively used.

Furthermore, it is provided that the heat shield has an opening for routing the ignition element through.

In one especially preferred embodiment of the invention, it is also provided that the combustion chamber is essentially axially symmetrical, that there is a baffle plate in the combustion chamber, and that the baffle plate has a given curvature in the axial direction. Due to the curvature of the baffle plate, there is a defined shaping of the baffle plate which is independent of temperature. For the baffle plates of the prior art which are made flat, this is, among others, not the case since, depending on the temperature, spontaneous changes of shape can occur which can adversely affect the combustion behavior of the burner.

It is preferred that there is a curvature in the direction of the burnout zone. In this way, a sufficient space in the region of the starting chamber is made available. Furthermore, it has been found that the curvature in the direction of the burnout zone does not have an adverse effect on the flow behavior in this zone. In particular, the pronounced swirled backflow region is maintained in the radially inner region of the burnout zone.

According to one preferred embodiment of the invention, it is provided that the outer periphery of the baffle plate defines a plane and that the ratio between the maximum axial distance of the baffle plate from this plane and the diameter of the baffle plate is between 0.07 and 0.21.

The most heavily arched point of the baffle plate is preferably essentially in the center of the arrangement with respect to the radial coordinate. From the plane which is defined by the outer periphery of the baffle plate, this point has an axial distance which is defined by the indicated ratio to the diameter.

In this connection, it is especially preferred that the ratio between the maximum axial distance of the baffle plate from the plane and the diameter of the baffle plate is roughly 0.14. For example the round diameter of baffle plate is roughly 40 mm, while the curvature has a value of roughly 5.7 mm.

The invention is based on the finding that the novel fuel supply with a fuel needle with a reduced exit cross section, especially in combination with the novel heat shield and the novel baffle plate, can greatly improve the operating behavior of a burner. This relates especially to the starting behavior, the stability of burner operation and possibilities with respect to the installation position of the burner in the motor vehicle.

The invention is explained by way of example with reference to the accompanying drawings using preferred embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a sectional view of the burner in accordance with the invention;

FIG. 2 is a perspective of a burner flange with the heat shield inserted into it; and

FIG. 3 is a perspective of the heat shield.

DETAILED DESCRIPTION OF THE INVENTION

In the following description of preferred embodiments of the invention, the same reference numbers label the same or comparable components.

FIG. 1 shows a sectional view of the burner in accordance with the invention. The burner 10 in accordance with the invention has a nozzle 12 which is securely joined to the heat shield 24. The heat shield 24 together with a burner tube 40 which is connected to the heat shield 24 defines a combustion chamber 22. The combustion chamber tube 40 is surrounded by an outer pipe 42 which forms the burner flange. A flame tube 38 is attached to this outer pipe 42. The connections between the heat shield 24 and the combustion chamber tube 40 or between the combustion chamber tube 40, the outer pipe 42 and the flame tube 38 are generally welded connections. On the fuel nozzle 12, there is a fuel supply 50 which has a metal pipe 52 for supplying of fuel and a fuel needle 14 for injection of fuel into the combustion chamber 22. Furthermore, in the region of the fuel nozzle 16, there are channels for supplying of primary combustion air into the fuel nozzle 20 which flows past the fuel needle 14 in order to then flow along the radially widening air guide of the fuel nozzle 12 in the direction of the combustion chamber, and finally, into the combustion chamber 22. The radial widening of the air guide achieves improved atomization due to the Venturi effect. Within the combustion chamber 22, there is also a baffle plate 36 which has an advantageous curvature. This curvature in the direction of the burnout zone 32 is advantageous since, in this way, heat-induced spontaneous changes in the shape of the baffle plate 36 are prevented. By curving the baffle plate 36 in the direction of the burnout zone 32, moreover, a sufficient space is available for accommodating the starting chamber 18. The wall which defines the starting chamber 18 is welded to the baffle plate 36.

FIG. 2 shows a perspective view of a burner flange with the heat shield inserted into it, and FIG. 3 shows a perspective view of heat shield 24. Furthermore, reference is likewise made below to burner components as shown in FIG. 1. The heat shield 24 has a central opening 48 through which the fuel-air mixture which has been delivered from the nozzle 12 enters the combustion chamber. Furthermore, there is a laterally arranged opening 34 through which the ignition element 20 is routed. On the heat shield 24, there are attachment pins 44, 46 to which the nozzle 12 is attached. The heat shield 24 also has a host of openings 26 through which secondary air can enter the combustion chamber 22. On the side of the heat shield 24 facing the combustion chamber 22, there are triangular air guide elements 28, 30. The air guide elements 28, 30 cause division of the secondary air based on the different angles relative to the radius of the heat shield 24.

A first group of air guide elements 28 are aligned at a large angle with respect to the radius of the heat shield 24, i.e., their alignment is essentially or almost tangential. Based on this alignment, the secondary air passing through the corresponding openings 26, with an exit flow direction indicated by the arrow, will overflow into the burnout zone 32 past the baffle plate 36 with a high angular momentum. This air which is provided with high angular momentum flows in the radially outlying region of the burnout zone 32 into the posterior region of the combustion chamber 22, i.e., into the region of the combustion chamber 22 which faces away from the heat shield 24, and then, with high swirling back in the central region in the direction of the baffle plate 36. Consequently advantageous mixing of the gaseous components in the burnout zone 32 occurs.

Another group of air guide elements 30 are aligned at a smaller angle relative to the radius of the heat shield 24 and also have a smaller angle relative to the surface of the heat shield 24 than the air guide elements 28. Consequently, these air guide elements 30 route the secondary air with an exit flow direction, indicated by another arrow, into the core region of the flame with low angular momentum; this especially benefits stable combustion chamber behavior.

Thus a novel spray burner is achieved which is improved with respect to the possible installation positions, the starting behavior and the behavior in continuous operation. Furthermore, problems with respect to the temperature-induced changes of the shape of the baffle plate are avoided.

The features of the invention disclosed in the above specification, the drawings and the claims can be important to the implementation of the invention both individually and also in any combination. 

1-14. (canceled)
 15. Burner for a heater for use in motor vehicles, comprising: a combustion chamber a burner nozzle for supplying and atomizing of fuel having a fuel needle for supplying fuel to the combustion chamber and a combustion air supply for supplying combustion air to the combustion chamber, and a starting zone in which ignition of the fuel to start the burner takes place, wherein the inside diameter of the fuel needle produces a predetermined exit speed of the fuel such that, during a starting phase of the burner, fuel in essentially unatomized form reaches the starting zone.
 16. Burner as claimed in claim 15, wherein the inside diameter of the fuel needle is between 0.5 mm and 0.7 mm.
 17. Burner as claimed in claim 15, wherein the inside diameter of the fuel needle is about 0.6 mm.
 18. Burner as claimed in claim 15, wherein the starting zone is a starting chamber into which an ignition element projects.
 19. Burner as claimed in claim 15, further comprising a heat shield having a generally centrally located passage therethrough that is surrounded by a ring openings in the heat shield; wherein: the heat shield is located between the burner nozzle and the combustion chamber, the combustion air supply comprises a primary air supply directed from the burner nozzle through the passage in the heat shield and a secondary air supply directed to the combustion chamber through said openings in the heat shield, and said openings are provided with air guide elements.
 20. Burner as claimed in claim 19, wherein the air guide elements are formed by tabs which are integral with the heat shield and which project toward the combustion chamber.
 21. Burner as claimed in claim 20, wherein the tabs are made at different angles relative to at least one of the radius and surface of the heat shield.
 22. Burner as claimed in claim 21, wherein the tabs are formed of groups of tabs, the tabs of each group being of essentially the same angle relative to said at least one of the radius and surface of the heat shield.
 23. Burner as claimed in claim 19, wherein: the combustion chamber has a burnout zone and secondary air is supplied to the burnout zone with a higher angular momentum than secondary air which is supplied to the starting zone.
 24. Burner as claimed in claim 19, wherein the heat shield has an opening for routing and ignition element through.
 25. Burner as claimed in claim 15, wherein: the combustion chamber is essentially axially symmetrical, there is a baffle plate in the combustion chamber, and wherein the baffle plate has a defined curvature in a downstream axial direction into the combustion chamber.
 26. Burner as claimed in claim 23, further comprising a baffle plate in the combustion chamber, the baffle plate having a defined curvature there in a direction toward the burnout zone.
 27. Burner as claimed in claim 26, wherein an outer periphery of the baffle plate defines a plane and wherein a ratio between a maximum axial distance of a portion of the baffle plate from this plane and the diameter of the baffle plate is between 0.07 and 0.21.
 28. Burner as claimed in claim 27, wherein the ratio between the maximum axial distance of the baffle plate from said plane and the diameter of the baffle plate is about 0.14.
 29. Burner as claimed in claim 25, wherein an outer periphery of the baffle plate defines a plane and wherein a ratio between a maximum axial distance of a portion of the baffle plate from this plane and the diameter of the baffle plate is between 0.07 and 0.21.
 30. Burner as claimed in claim 29, wherein the ratio between the maximum axial distance of the baffle plate from said plane and the diameter of the baffle plate is about 0.14. 